Tag: torque control

Deprag's New Adaptive Direct Fastening System is a revolution automatic flow form screwdriving.

The use of flow form screws into two non-drilled sheets requires high down force and high speed to heat and form the hole. It is a complex assembly because to achieve optimal cycle times and proper funnel and thread forming, the down force and feed speed needs adjusted during the various stages of the screw assembly so that the funnel and thread forming can be done reliably.

Traditional systems required numerous pre-tests to determine the timing of the piercing point. Switching parameters too early leads to improper funnel formation and longer assembly times, too late can lead to thread damage.

Deprag's Adaptive DFS is able to sense the exact piercing point as well as other key stages in the screw assembly and switches parameters accordingly assuring:

automatic adaptation to variances in the screw and part

the highest process reliability

shortest possible cycle times

optimised funnel forming

reduced set up times

a more flexible system

minimise damaged threads

Other features of the Adaptive Direct Fastening System are:

Active nosepiece jaws that hold the screw firmly until drilling has started

Adjustable down holder force

High down pressure applied directly in line with the screw

Head first screw feeding to minimise damage to the screw’s tip

Fast interchange of the mouthpiece for minimal downtime

Lock stroke for underfloor applications

Max Speed: 8000rpm, freely programmable

Max torque: 15Nm, freely programmable

Feed stroke: upto 3000N, freely programmable force and distance

Max Downholder force: 1200N, freely adjustable

Weight: 35kg

Assembly at any angle or upside down.

Maintenance friendly

Complete with industrial PC to set parameters, control the screwdriving and to analyse trends

Fully automated assembly systems not only offer fast assembly, but they also guarantee a higher level of quality control. Unfortunately, professionally designed, reliable automated assembly equipment is expensive and often inflexible. Unless there are very large volumes over a length of time, many automatic assembly automation projects are not viable.

The solution? Intelligent – Manual – Assembly cells.

Increasingly manufacturers are finding a middle ground between hand assembly and fully automated assembly cells. Unknown product life cycles, unpredictable demand and sudden downturns means that manufacturers are looking for the most flexible system possible. With modern screwdriving, screwfeeders and controllers we able to guarantee complete process control, minimize assembly time and provide flexibility at the same time.

A typical Intelligent Manual Assembly Cell will consist of one or more hand guided screwdrivers mounted in a position control stand connected to one or more screw feeders.

The screwdriver is typically freely programmable and different torques can be called up depending on the part to be assembled and the position of the screwdriver.

The torque of each screw is monitored and recorded. If a screw is not assembled to torque or depth the operator will be alerted.

Screws can be automatically fed to the screwdriver after every assembly. We can even feed and assemble different screws for the one part.

The torque, angle and assembly time of each screw can be monitored

Other assembly tasks can be monitored by the controller and additional sensors

The workstation can be designed for the assembly of numerous different parts

Flexible screw assembly with full quality control

Peter Smith, production engineer at a well-known manufacturer of heating control units explained his requirements:

“Our heating control units are available, according to type and size of heating system, in the most varied of designs. With the recent introduction of our new control units we are starting three separate series, our HCU25, HCU50 and HCU100. When launching our new series onto the market we are unable to estimate the expected production amounts accurately. It is also difficult to plan out how the quantities required of each individual version will develop in relation to one other. It is for exactly this reason that we require highly flexible assembly equipment. Ideally production should be able to be simply, reliably and economically adapted to each of the product versions. Additionally for our HCU assembly we have the highest requirements for processing reliability as is usual for electronic components. The sequential order of assembly must be guaranteed and each step must be documented and integrated into our manufacturing execution systems”.

Normally this requirement of a strict sequence and documentation calls for automation. However in the costs of automation and unknown production numbers excluded automation.

Deprag were able to offer an intelligent manual assembly cell that could be used to assemble all three HCU’s even though they each used different parts, sequence of assembly, different screws and torques.

Using interchangeable adapters, assembly can be easily converted to the various sizes of HCU25, HCU50 and HCU100. Work piece adapters are equipped with integrated sensor technology and communicate with a superior controller.

Furthermore the assembly required ESD safe and technical cleanliness. The screws were fed with sword feeders instead of vibratory feeders and the assembly and positioning of the screws was done with vacuum pick up and particle killers.

Mr Smith says –

“The collaboration with DEPRAG has been impressive. All our technical requirements were realised with already existing harmonised standard components within the shortest space of time. And what is particularly important for us, all system components come to us from one source. When we need to increase our production capacity we can flexibly expand our assembly line”.

Almost every component of a product has a specification with an acceptable tolerance. The component will have functional and physical attributes that can be measured and specified. If the attributes are outside of the predetermined tolerance it will be rejected.

Screw joints are integral parts of any assembly. Loose or stripped screws at best can cause annoying rattles and in a worst case they can cause complete failure of a product. In any case, the long term costs of warranty repairs and harm to a brand will far outweigh the short term costs of correctly designing and specifying the torque, accuracy and type of screwdriving equipment for your assembly line.

Manual Screw Driving station with Automatic screw feeding and position control

Quite often we still find that many manufacturers do not have a torque specification for each of their screw assemblies, let alone calibrate their precision screwdriver or monitor their accuracy. Many screwdrivers in production have no torque control or are easily adjusted by the production line workers, while others are simply not checked until something goes wrong (oops too late!!).

“As long as the screw is not stripped”, “As long as a screw is there” are phrases our sales engineers often hear when they ask about the torque specifications. Unfortunately that is not good enough these days. There is no way of knowing if a screw is stripped after assembly unless there is some kind of supervision system or the operators care enough to reject the part as it happens. Just because an inspector sees that all of the screws are assembled does not mean that they are all assembled to torque or not stripped. Testing every screw after assembly with a torque wrench is a waste of time and inaccurate, especially when you can get screwdrivers that assemble screws more accurately than any subsequent testing method.

Customers expect more from Australian manufactured goods. You can imagine the disappointment of a customer who has chosen Australian made products and finds that it is faulty because of something as simple as a stripped or loose screw? He would probably think he may as well have bought the Chinese product for a fraction of the price. What if that company was one of your main export customers?

What’s the solution?

We recommend that manufacturers:

Invest in torque analysis of their parts to first set a torque specification. The most basic requirement for any serious manufacturer who uses screws, should be to have torque specifications and a tolerance for every screw joint.

Regularly check the calibration of the screwdrivers. The Average and Standard Deviation of the measurements need to be checked. The frequency of the checks depend on the quality of the screwdrivers and the importance of the screw joints.

Only buy production quality screwdrivers. They are safer (quieter and more ergonomic), last longer and are more accurate than cheap drivers.

Consider screwdrivers with supervisors to count the screws per part and check that torque has been reached on every screw.

For complete quality control we can also supply Intelligent Manual Workstations where position controlled equipment monitors the position of the screwdriver and can even select different tightening strategies based on the screw position.

If the joint is important, consider screwdrivers that measure and document the torque for each screw – don’t leave it up to the operator to tell you that there is a problem!!

How accurate do the screwdrivers need to be?

This depends on the tolerance that is required. Generally industry expects a failure rate of better than 0.6 failures per million assemblies. If the screwdriver is capable of a standard deviation (accuracy) of less than ±3% with a torque tolerance of ±10% of the target torque, then we can safely meet the failure rate of 0.6 per million. If the screwdriver can achieve an SD of better than ±1% (for example our EC Servo Screwdrivers), then a tolerance of ±5% is possible.

Screwdriving Quality Control

We have over 20 years experience in helping customers with screw assembly productivity and quality control issues. Please don’t hesitate to contact us for advice on your applications.